Multi-layered bags with discrete non-continuous lamination

ABSTRACT

Multi-layer bags may be formed to include first and second sidewalls joined along a first side edge, an opposite second side edge, and a closed bottom edge. The first and second layers may be non-continuously laminated together in discrete sections to include bonded regions in which the layers are bonded and unbonded regions in which the layers are not bonded. Such a bag may be described as a “bag-in-a-bag” type configuration in which the inner bag is non-continuously bonded to the outer bag. The inventors have surprisingly found that such configurations of non-continuous bonding provides increased and unexpected strength properties to the multi-layer films and bags.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent application Ser. No. 13/299,512 filed Nov. 18, 2011 and entitled MULTI-LAYERED BAG WITH DISCRETE NON-CONTINUOUS LAMINATION, which is a continuation in part of U.S. patent application Ser. No. 12/947,025 filed Nov. 16, 2010, now U.S. Pat. No. 8,603,609 issued on Dec. 10, 2013 and entitled DISCONTINUOUSLY LAMINATED FILM, which claims the benefit of U.S. Provisional Application No. 61/261,673, filed Nov. 16, 2009. Each of the above-referenced applications is hereby incorporated by reference in its entirety.

BACKGROUND OF THE INVENTION

1. The Field of the Invention

The present invention relates generally to thermoplastic films. Specifically, the invention relates to stretched thermoplastic films with visually distinct regions created by stretching the films.

2. Background and Relevant Art

Thermoplastic films are a common component in various commercial and consumer products. For example, grocery bags, trash bags, sacks, and packaging materials are products that are commonly made from thermoplastic films. Additionally, feminine hygiene products, baby diapers, adult incontinence products, and many other products include thermoplastic films to one extent or another.

Thermoplastic films have a variety of different strength parameters that manufacturers of products incorporating a thermoplastic film component may attempt to manipulate to ensure that the film is suitable for use its intended use. For example, manufacturers may attempt to increase or otherwise control the tensile strength, tear resistance, and impact resistance of a thermoplastic film. One way manufacturers may attempt to control or change the material properties of a thermoplastic film is by stretching the film. Common directions of stretching include “machine direction” and “transverse direction” stretching. As used herein, the term “machine direction” or “MD” refers to the direction along the length of the film, or in other words, the direction of the film as the film is formed during extrusion and/or coating. As used herein, the term “transverse direction” or “TD” refers to the direction across the film or perpendicular to the machine direction.

Common ways of stretching film in the machine direction include machine direction orientation (“MDO”) and incremental stretching. MDO involves stretching the film between two pairs of smooth rollers. Commonly MDO involves running a film through the nips of sequential pairs of smooth rollers. The first pair of rollers rotates at a speed less than that of the second pair of rollers. The difference in speed of rotation of the pairs of rollers can cause the film between the pairs of rollers to stretch. The ratio of the roller speeds will roughly determine the amount that the film is stretched. For example, if the first pair of rollers is rotating at 100 feet per minute (“fpm”) and the second pair of rollers is rotating at 500 fpm, the rollers will stretch the film to roughly five times its original length. MDO stretches the film continuously in the machine direction and is often used to create an oriented film.

Incremental stretching of thermoplastic film, on the other hand, typically involves running the film between grooved or toothed rollers. The grooves or teeth on the rollers intermesh and stretch the film as the film passes between the rollers. Incremental stretching can stretch a film in many small increments that are spaced across the film. The depth at which the intermeshing teeth engage can control the degree of stretching. Often, incremental stretching of films is referred to as ring rolling.

In addition to allowing for the modification or tailoring of the strength of a film, stretching of a film can also reduce the thickness of the film. Stretched films of reduced thickness can allow manufacturers to use less thermoplastic material to form a product of a given surface area or size. Unfortunately, stretching thermoplastic using conventional methods can weaken the film.

One common use of thermoplastic films is as bags for liners in trash or refuse receptacles. Another common use of thermoplastic films is as flexible plastic bags for storing food items.

BRIEF SUMMARY OF THE INVENTION

Implementations of the present invention solve one or more problems in the art with apparatus and methods for creating multi-layered bags with discrete non-continuous lamentation. In particular, one or more implementations provide for forming bonds between adjacent layers of a multi-layer film or bag that are relatively light such that forces acting on the multi-layer film are first absorbed by breaking the bonds rather than, or prior to, tearing or otherwise causing the failure of the layers of the multi-layer film or bag. Such implementations can provide an overall thinner film employing a reduced amount of raw material that nonetheless has maintained or increased strength parameters. Alternatively, such implementations can use a given amount of raw material and provide a film with increased strength parameters. Furthermore, discrete areas of the multi-layered bags can include different bonding to provide different strength and/or aesthetic characteristics to the multi-layered bags.

For example, one implementation of a thermoplastic bag with a bag-in-bag configuration includes a first thermoplastic bag and a second thermoplastic bag positioned within the first thermoplastic bag. Each of the first and second thermoplastic bags can have at least a bottom section, a middle section, and an upper section. The first thermoplastic bag also includes first and second opposing sidewalls joined together along three edges. The second thermoplastic bag includes third and fourth opposing sidewalls joined together along three edges. A plurality of non-continuous bonded regions secure at least one of the respective bottom sections, middle sections, or upper sections of the first thermoplastic bag and the second thermoplastic bag together.

Another implementation of the present invention includes a multi-layered bag comprising a first sidewall comprising a first layer of a thermoplastic material and an adjacent second layer of thermoplastic material. The multi-layered bag also includes a second sidewall comprising a first layer of a thermoplastic material and an adjacent second layer of thermoplastic material. The second sidewall is joined to the first sidewall along a first side edge, an opposing second side edge, and a bottom edge. At least a portion of the respective top edges of the first and second sidewalls define an opening of the multi-layered bag. A first plurality of non-continuous bonds secures at least one section of the first and second layers of the first sidewall together. Additionally, a second plurality of non-continuous bonds secures at least another section of the first and second layers of the first sidewall together. The second plurality of non-continuous bonds differs from the first plurality of non-continuous bonds.

In addition to the forgoing, a method for forming a discretely laminated, multi-layered thermoplastic bag may involve providing first and second thermoplastic films. The method can also involve non-continuously laminating a portion of the first thermoplastic film to the second thermoplastic film by a process selected from the group consisting of adhesive bonding, ultrasonic bonding, embossing, ring rolling, SELFing, and combinations thereof. Additionally, the method can involve joining at least two edges of the first thermoplastic film and the second thermoplastic film together to form a bag configuration.

Additional features and advantages of exemplary embodiments of the present invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of such exemplary embodiments. The features and advantages of such embodiments may be realized and obtained by means of the instruments and combinations particularly pointed out in the appended claims. These and other features will become more fully apparent from the following description and appended claims, or may be learned by the practice of such exemplary embodiments as set forth hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to describe the manner in which the above-recited and other advantages and features of the invention can be obtained, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. It should be noted that the figures are not drawn to scale, and that elements of similar structure or function are generally represented by like reference numerals for illustrative purposes throughout the figures. Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered to be limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:

FIG. 1A illustrates a schematic diagram of a multi-layered film being lightly laminated by MD intermeshing rollers in accordance with one or more implementations of the present invention;

FIG. 1B illustrates an enlarged view of two initially separate thermoplastic films passing together through the intermeshing rollers of FIG. 1A taken along the circle 1B of FIG. 1 to form a multi-layered lightly-laminated;

FIG. 1C illustrates an enlarged view of three initially separate thermoplastic films passing together through the intermeshing rollers of FIG. 1A to form a multi-layered lightly-laminated;

FIG. 2 illustrates a view of a multi-layered lightly-laminated thermoplastic film created by the intermeshing rollers of FIG. 1A;

FIG. 3 illustrates a schematic diagram of a multi-layered thermoplastic film being lightly laminated by TD intermeshing rollers in accordance with one or more implementations of the present invention;

FIG. 4 illustrates a view of a multi-layered lightly-laminated thermoplastic film created by the intermeshing rollers of FIG. 3;

FIG. 5 illustrates a view of a multi-layered lightly-laminated thermoplastic film created by the intermeshing rollers of both FIG. 1A and FIG. 3;

FIG. 6 illustrates a view of a multi-layered lightly-laminated thermoplastic film created by diagonal direction intermeshing rollers in accordance with one or more implementations of the present invention;

FIG. 7 illustrates a schematic diagram of a set of intermeshing rollers used to form a structural elastic like film (SELF) by imparting strainable networks into the film while lightly laminating adjacent layers of a film in accordance with one or more implementations of the present invention;

FIG. 8 illustrates a view of a multi-layered lightly-laminated thermoplastic film created by the intermeshing rollers of FIG. 7;

FIG. 9 illustrates a view of another multi-layered lightly-laminated thermoplastic film including strainable networks in accordance with one or more implementations of the present invention;

FIG. 10A illustrates a view of yet another multi-layered lightly-laminated thermoplastic film including strainable networks in accordance with one or more implementations of the present invention;

FIG. 10B illustrates a cut away perspective view across and through the block pattern of FIG. 10A;

FIG. 11A illustrates a schematic diagram of another implementation of intermeshing rollers for use in accordance with one or more implementations of the present invention;

FIG. 11B illustrates a close up of the protrusions and intermeshing recessions of the rollers of FIG. 11A;

FIG. 11C illustrates a view of a multi-layered lightly-laminated thermoplastic film created by the intermeshing rollers of FIG. 11A;

FIG. 12A illustrates a multi-layered bag with discrete non-continuous lamination in accordance with one or more implementations of the present invention;

FIG. 12B illustrates a cross-sectional view of the bag of FIG. 12A taken along the line 12B-12B of FIG. 12A;

FIG. 13 illustrates another multi-layered bag with discrete non-continuous lamination in accordance with one or more implementations of the present invention;

FIG. 14 illustrates yet another multi-layered bag with discrete non-continuous lamination in accordance with one or more implementations of the present invention;

FIG. 15 illustrates a another multi-layered bag with discrete non-continuous lamination incorporating sections of different patterns of lightly bonded regions in accordance with one or more implementations of the present invention;

FIG. 16 illustrates another multi-layered bag with discrete non-continuous lamination incorporating sections of different patterns of lightly bonded regions in accordance with one or more implementations of the present invention;

FIG. 17 illustrates another multi-layered bag with discrete non-continuous lamination in accordance with one or more implementations of the present invention;

FIG. 18 illustrates another multi-layered bag with discrete non-continuous lamination incorporating a top section having lightly bonded regions in accordance with one or more implementations of the present invention;

FIG. 19 illustrates another multi-layered bag with discrete non-continuous lamination with another bond pattern in accordance with one or more implementations of the present invention;

FIG. 20 illustrates another multi-layered bag with discrete non-continuous lamination with yet another bond pattern in accordance with one or more implementations of the present invention;

FIG. 21 illustrates another multi-layered bag with discrete non-continuous lamination incorporating a top section and a bottom section having lightly bonded regions in accordance with one or more implementations of the present invention;

FIG. 22 illustrates another multi-layered bag with discrete non-continuous lamination incorporating a top section having lightly bonded regions in accordance with one or more implementations of the present invention;

FIG. 23 illustrates another multi-layered bag with discrete non-continuous lamination incorporating a top section and a bottom section having lightly bonded regions, each of a different pattern, in accordance with one or more implementations of the present invention;

FIG. 24 illustrates another multi-layered bag with discrete non-continuous lamination incorporating a top section having lightly bonded regions in accordance with one or more implementations of the present invention;

FIG. 25 illustrates still another multi-layered bag with discrete non-continuous lamination incorporating a top section and a bottom section having lightly bonded regions in accordance with one or more implementations of the present invention;

FIG. 26 illustrates a schematic diagram of a bag manufacturing process in accordance with one or more implementations of the present invention;

FIG. 27 illustrates a schematic diagram of another bag manufacturing process in accordance with one or more implementations of the present invention; and

FIG. 28 illustrates a schematic diagram of another bag manufacturing process in accordance with one or more implementations of the present invention.

DETAILED DESCRIPTION

One or more implementations of the present invention include apparatus and methods for creating multi-layered bags with discrete non-continuous lamentation. In particular, one or more implementations provide for forming bonds between adjacent layers of a multi-layer film or bag that are relatively light such that forces acting on the multi-layer film are first absorbed by breaking the bonds rather than, or prior to, tearing or otherwise causing the failure of the layers of the multi-layer film or bag. Such implementations can provide an overall thinner film employing a reduced amount of raw material that nonetheless has maintained or increased strength parameters. Alternatively, such implementations can use a given amount of raw material and provide a film with increased strength parameters. Furthermore, discrete areas of the multi-layered bags can include different bonding to provide different strength and/or aesthetic characteristics to the multi-layered bags.

In particular, the non-continuous bonds or bond regions of adjacent layers of multi-layer films or bags in accordance with one or more implementations can act to first absorb forces via breaking of the bonds prior to allowing that same force to cause failure of the individual layers of the multi-layer film or bag. Such action can provide increased strength to the multi-layer film or bag. In one or more implementations, the non-continuous bonds or bond regions include a bond strength that is advantageously less than a weakest tear resistance of each of the individual films so as to cause the bonds to fail prior to failing of the film layers. Indeed, one or more implementations include bonds that the release just prior to any localized tearing of the layers of the multi-layer bag.

Thus, in one or more implementations, the non-continuous bonds or bond regions of a multi-layer film or bag can fail before either of the individual layers undergo molecular-level deformation. For example, an applied strain can pull the non-continuous bonds or bond regions apart prior to any molecular-level deformation (stretching, tearing, puncturing, etc.) of the individual film layers. In other words, the light bonds or bond regions can provide less resistive force to an applied strain than molecular-level deformation of any of the layers of the multi-layer film or bag. The inventors have surprisingly found that such a configuration of light bonding can provide increased strength properties to the multi-layer film or bag as compared to a film or bag with a monolayer equal thickness or a multi-layer film or bag in which the plurality of layers are tightly bonded together (e.g., coextruded).

One or more implementations of the present invention provide for tailoring the bonds or bond regions between layers of a multi-layer bag in different regions of the bag. For example, one or more implementations include modifying or tailoring one or more of bond strength, bond density, bond pattern, bond type and/or bond size of different sections of a multi-layer film or bag to deliver a bag with zones or sections with tailored strength and/or aesthetic characteristics.

Relatively weak bonding of the two or more layers of the multi-layer film or bag can be accomplished through one or more suitable techniques. For example, bonding may be achieved by pressure (for example MD ring rolling, TD ring rolling, stainable network lamination, or embossing), or with a combination of heat and pressure. Alternately, the film layers can be lightly laminated by ultrasonic bonding. Alternately, the films can be laminated by adhesives. Treatment with a Corona discharge can enhance any of the above methods. Prior to lamination, the separate layers can be flat film or can be subject to separate processes, such as stretching, slitting, coating and printing, and corona treatment.

As used herein, the terms “lamination,” “laminate,” and “laminated film,” refer to the process and resulting product made by bonding together two or more layers of film or other material. The term “bonding”, when used in reference to bonding of multiple layers of a multi-layer film, may be used interchangeably with “lamination” of the layers. According to methods of the present invention, adjacent layers of a multi-layer film are laminated or bonded to one another. The bonding purposely results in a relatively weak bond between the layers that has a bond strength that is less than the strength of the weakest layer of the film. This allows the lamination bonds to fail before the film layer, and thus the film, fails.

The term laminate is also inclusive of coextruded multilayer films comprising one or more tie layers. As a verb, “laminate” means to affix or adhere (by means of, for example, adhesive bonding, pressure bonding, ultrasonic bonding, corona lamination, and the like) two or more separately made film articles to one another so as to form a multi-layer structure. As a noun, “laminate” means a product produced by the affixing or adhering just described.

The individual layers of the multi-layer film may each themselves comprise a plurality of laminated layers. Such layers may be significantly more tightly bonded together than the bonding provided by the purposely weak non-continuous bonding in the finished multi-layer film. Both tight and relatively weak lamination can be accomplished by joining layers by mechanical pressure, joining layers with adhesives, joining with heat and pressure, spread coating, extrusion coating, and combinations thereof. Adjacent sub-layers of an individual layer may be coextruded. Coextrusion results in tight bonding so that the bond strength is greater than the tear resistance of the resulting laminate (i.e., rather than allowing adjacent layers to be peeled apart through breakage of the lamination bonds, the film will tear).

In one or more implementations, the light lamination or bonding between layers of a multi-layer film may be non-continuous (i.e., discontinuous or partial discontinuous). As used herein the terms “discontinuous bonding” or “discontinuous lamination” refers to lamination of two or more layers where the lamination is not continuous in the machine direction and not continuous in the transverse direction. More particularly, discontinuous lamination refers to lamination of two or more layers with repeating bonded patterns broken up by repeating un-bonded areas in both the machine direction and the transverse direction of the film.

As used herein the terms “partially discontinuous bonding” or “partially discontinuous lamination” refers to lamination of two or more layers where the lamination is substantially continuous in the machine direction or in the transverse direction, but not continuous in the other of the machine direction or the transverse direction. Alternately, partially discontinuous lamination refers to lamination of two or more layers where the lamination is substantially continuous in the width of the article but not continuous in the height of the article, or substantially continuous in the height of the article but not continuous in the width of the article. More particularly, partially discontinuous lamination refers to lamination of two or more layers with repeating bonded patterns broken up by repeating unbounded areas in either the machine direction or the transverse direction.

As used herein, the term “flexible” refers to materials that are capable of being flexed or bent, especially repeatedly, such that they are pliant and yieldable in response to externally applied forces. Accordingly, “flexible” is substantially opposite in meaning to the terms inflexible, rigid, or unyielding. Materials and structures that are flexible, therefore, may be altered in shape and structure to accommodate external forces and to conform to the shape of objects brought into contact with them without losing their integrity. In accordance with further prior art materials, web materials are provided which exhibit an “elastic-like” behavior in the direction of applied strain without the use of added traditional elastic. As used herein, the term “elastic-like” describes the behavior of web materials which when subjected to an applied strain, the web materials extend in the direction of applied strain, and when the applied strain is released the web materials return, to a degree, to their pre-strained condition.

As used herein, the term “starting gauge” or “initial gauge” refers to the average distance between the major surfaces of a film before it is incrementally stretched so as to discontinuously bond adjacent layers together. Of course, it is also possible to stretch one or more of the individual layers before they are discontinuously bonded together.

Methods of providing relatively weak bonding of adjacent layers (i.e., so that the bond strength is less than a weakest tear resistance of the individual layers) can include many techniques, such as adhesive bonding, pressure bonding, ultrasonic bonding, and corona lamination. MD ring rolling, TD ring rolling, or other ring rolling processes (e.g., DD ring rolling or ring rolling that results in a thermoplastic film with strainable networks), and combinations thereof may be used to non-continuously bond adjacent layers of the multilayer film, as will be described in further detail below. Film Materials

As an initial matter, one or more layers of the films can comprise any flexible or pliable material comprising a thermoplastic material and that can be formed or drawn into a web or film. As described above, the film includes a plurality of layers of thermoplastic films. Each individual film layer may itself include a single layer or multiple layers. Adjuncts may also be included, as desired (e.g., pigments, slip agents, anti-block agents, tackifiers, or combinations thereof). The thermoplastic material of the films of one or more implementations can include, but are not limited to, thermoplastic polyolefins, including polyethylene, polypropylene, and copolymers thereof. Besides ethylene and propylene, exemplary copolymer olefins include, but are not limited to, ethylene vinylacetate (EVA), ethylene methyl acrylate (EMA) and ethylene acrylic acid (EAA), or blends of such olefins. Various other suitable olefins and polyolefins will be apparent to one of skill in the art.

Other examples of polymers suitable for use as films in accordance with the present invention include elastomeric polymers. Suitable elastomeric polymers may also be biodegradable or environmentally degradable. Suitable elastomeric polymers for the film include poly(ethylene-butene), poly(ethylene-hexene), poly(ethylene-octene), poly(ethylene-propylene), poly(styrene-butadiene-styrene), poly(styrene-isoprene-styrene), poly(styrene-ethylene-butylene-styrene), poly(ester-ether), poly(ether-amide), poly(ethylene-vinylacetate), poly(ethylene-methylacrylate), poly(ethylene-acrylic acid), poly(ethylene butylacrylate), polyurethane, poly(ethylene-propylene-diene), ethylene-propylene rubber, and combinations thereof.

In at least one implementation of the present invention, the film can include linear low density polyethylene. The term “linear low density polyethylene” (LLDPE) as used herein is defined to mean a copolymer of ethylene and a minor amount of an alkene containing 4 to 10 carbon atoms, having a density of from about 0.910 to about 0.926 g/cm³, and a melt index (MI) of from about 0.5 to about 10. For example, one or more implementations of the present invention can use an octene co-monomer, solution phase LLDPE (MI=1.1; p=0.920). Additionally, other implementations of the present invention can use a gas phase LLDPE, which is a hexene gas phase LLDPE formulated with slip/AB (MI=1.0; p=0.920). One will appreciate that the present invention is not limited to LLDPE, and can include “high density polyethylene” (HDPE), “low density polyethylene” (LDPE), and “very low density polyethylene” (VLDPE). Indeed films made from any of the previously mentioned thermoplastic materials or combinations thereof can be suitable for use with the present invention.

One will appreciate in light of the disclosure herein that manufacturers may form the individual films or webs to be non-continuously bonded together so as to provide improved strength characteristics using a wide variety of techniques. For example, a manufacturer can form a precursor mix of the thermoplastic material including any optional additives. The manufacturer can then form the film(s) from the precursor mix using conventional flat extrusion, cast extrusion, or coextrusion to produce monolayer, bilayer, or multilayered films. In any case, the resulting film will be discontinuously bonded to another film at a later stage to provide the benefits associated with the present invention.

Alternative to conventional flat extrusion or cast extrusion processes, a manufacturer can form the films using other suitable processes, such as, a blown film process to produce monolayer, bilayer, or multilayered films, which are subsequently discontinuously bonded with another film layer at a later stage. If desired for a given end use, the manufacturer can orient the films by trapped bubble, tenterframe, or other suitable processes. Additionally, the manufacturer can optionally anneal the films.

The extruder used can be of a conventional design using a die, which will provide the desired gauge. Some useful extruders are described in U.S. Pat. Nos. 4,814,135; 4,857,600; 5,076,988; 5,153,382; each of which are incorporated herein by reference in their entirety. Examples of various extruders, which can be used in producing the films to be used with the present invention, can be a single screw type modified with a blown film die, an air ring, and continuous take off equipment.

In one or more implementations, a manufacturer can use multiple extruders to supply different melt streams, which a feed block can order into different channels of a multi-channel die. The multiple extruders can allow a manufacturer to form a multi-layered film with layers having different compositions. Such multi-layer film may later be non-continuously laminated with another layer of film to provide the benefits of the present invention.

In a blown film process, the die can be an upright cylinder with a circular opening. Rollers can pull molten plastic upward away from the die. An air-ring can cool the film as the film travels upwards. An air outlet can force compressed air into the center of the extruded circular profile, creating a bubble. The air can expand the extruded circular cross section by a multiple of the die diameter. This ratio is called the “blow-up ratio.” When using a blown film process, the manufacturer can collapse the film to double the plies of the film. Alternatively, the manufacturer can cut and fold the film, or cut and leave the film unfolded.

The films of one or more implementations of the present invention can have a starting gauge between about 0.1 mils to about 20 mils, suitably from about 0.2 mils to about 4 mils, suitably in the range of about 0.3 mils to about 2 mils, suitably from about 0.6 mils to about 1.25 mils, suitably from about 0.9 mils to about 1.1 mils, suitably from about 0.3 mils to about 0.7 mils, and suitably from about 0.4 mils and about 0.6 mils. Additionally, the starting gauge of films of one or more implementations of the present invention may not be uniform. Thus, the starting gauge of films of one or more implementations of the present invention may vary along the length and/or width of the film.

As previously mentioned, according to one implementation of the invention, the separate layers of the multi-layer film are non-continuously, lightly bonded to one another. FIGS. 1A-1C illustrate exemplary processes of partially discontinuously bonding adjacent layers of a multi-layer thermoplastic film in accordance with an implementation of the present invention. In particular, FIGS. 1A-1C illustrate an MD ring rolling process that partially discontinuously laminates the individual adjacent layers of thermoplastic multi-layered film 10 by passing the multi-layered film 10 through a pair of MD intermeshing rollers 12, 14. As a result of MD ring rolling, the multi-layered film 10 is also intermittently stretched in the machine direction MD.

As shown by the FIGS. 1A-1C, the first roller 12 and the second roller 14 can each have a generally cylindrical shape. The rollers 12, 14 may be made of cast and/or machined metal, such as, steel, aluminum, or any other suitable material. The rollers 12, 14 can rotate in opposite directions about parallel axes of rotation. For example, FIG. 1A illustrates that the first roller 12 can rotate about a first axis 16 of rotation in a counterclockwise direction 18. FIG. 1A also illustrates that the second roller 14 can rotate about a second axis 20 of rotation in a clockwise direction 22. The axes of rotation 16, 20 can be parallel to the transverse direction TD and perpendicular to the machine direction MD.

The intermeshing rollers 12, 14 can closely resemble fine pitch spur gears. In particular, the rollers 12, 14 can include a plurality of protruding ridges 24, 26. The ridges 24, 26 can extend along the rollers 12, 14 in a direction generally parallel to axes of rotation 16, 20. Furthermore, the ridges 24, 26 can extend generally radially outward from the axes of rotation 16, 20. The tips of ridges 24, 26 can have a variety of different shapes and configurations. For example, the tips of the ridges 24, 26 can have a rounded shape as shown in FIGS. 1B-1C. In alternative implementations, the tips of the ridges 24, 26 can have sharp angled corners. FIGS. 1A-1C also illustrate that grooves 28, 30 can separate adjacent ridges 24, 26.

The ridges 24 on the first roller 12 can be offset or staggered with respect to the ridges 26 on the second roller 14. Thus, the grooves 28 of the first roller 12 can receive the ridges 26 of the second roller 14, as the rollers 12, 14 intermesh. Similarly, the grooves 30 of the second roller 14 can receive the ridges 24 of the first roller 12.

One will appreciate in light of the disclosure herein that the configuration of the ridges 24, 26 and grooves 28, 30 can prevent contact between ridges 24, 26 during intermeshing so that no rotational torque is transmitted during operation. Additionally, the configuration of the ridges 24, 26 and grooves 28, 30 can affect the amount of stretching and the bond strength resulting from partially discontinuous lamination as the film passes through intermeshing rollers 12, 14.

Referring specifically to FIGS. 1B-1C, various features of the ridges 24, 26 and grooves 28, 30 are shown in greater detail. The pitch and depth of engagement of the ridges 24, 26 can determine, at least in part, the amount of incremental stretching and partially discontinuous lamination caused by the intermeshing rollers 12, 14. As shown by FIGS. 1B-1C, the pitch 32 is the distance between the tips of two adjacent ridges on the same roller. The “depth of engagement” (“DOE”) 34 is the amount of overlap between ridges 24, 26 of the different rollers 12, 14 during intermeshing.

The ratio of DOE 34 to pitch 32 can determine, at least in part, the bond strength provided by the partially discontinuous bonding. According to one embodiment, the ratio of DOE to pitch provided by any ring rolling operation is less than about 1.1:1, suitably less than about 1.0:1, suitably between about 0.5:1 and about 1.0:1, or suitably between about 0.8:1 and about 0.9:1.

As shown by FIG. 1A, the direction of travel of the multi-layered film 10 through the intermeshing rollers 12, 14 is parallel to the machine direction and perpendicular to the transverse direction. As the thermoplastic multi-layered film 10 passes between the intermeshing rollers 12, 14, the ridges 24, 26 can incrementally stretch the multi-layered film 10 in the machine direction. In one or more implementations, stretching the multi-layered film 10 in the machine direction can reduce the gauge of the film and increase the length of the multi-layered film 10. In other implementations, the multi-layered film 10 may rebound after stretching such that the gauge of the multi-layered film 10 is not decreased. Furthermore, in one or more implementations, stretching the film 10 in the machine direction can reduce the width of the multi-layered film 10. For example, as the multi-layered film 10 is lengthened in the machine direction, the film's length can be reduced in the transverse direction.

In particular, as the multi-layered film 10 proceeds between the intermeshing rollers 12, 14, the ridges 24 of the first roller 12 can push the multi-layered film 10 into the grooves 30 of the second roller 14 and vice versa. The pulling of the multi-layered film 10 by the ridges 24, 26 can stretch the multi-layered film 10. The rollers 12, 14 may not stretch the multi-layered film 10 evenly along its length. Specifically, the rollers 12, 14 can stretch the portions of the film 10 between the ridges 24, 26 more than the portions of the multi-layered film 10 that contact the ridges 24, 26. Thus, the rollers 12, 14 can impart or form a generally striped pattern 36 into the multi-layered film 10. As used herein, the terms “impart” and “form” refer to the creation of a desired structure or geometry in a film upon stretching the film that will at least partially retain the desired structure or geometry when the film is no longer subject to any strains or externally applied forces.

FIGS. 1A-1C illustrate that the film 10 a (i.e., the film that is yet to pass through the intermeshing rollers 12, 14) can have a substantially flat top surface 38 and substantially flat bottom surface 40. As seen in FIG. 1B, the multi-layer film 10 a may comprise two layers 10 c and 10 d that are initially separate from one another. The film 10 a can have an initial thickness or starting gauge 42 (i.e., the sum of 42 a and 42 b) extending between its major surfaces (i.e., the top surface 38 and the bottom surface 40). In at least one implementation, the starting gauge 42, as well as the gauge 42 a, 42 b of individual layers 10 c and 10 d can be substantially uniform along the length of the multi-layer film 10 a. Because the inner surfaces of each layer 10 c and 10 d are somewhat tacky, the layers become lightly bonded together as they are pulled through and stretched by intermeshing rollers 12, 14. Those areas that are stretched become lightly bonded together.

In one or more implementations, the pre-laminated film 10 a need not have an entirely flat top surface 38, but may be rough or uneven. Similarly, bottom surface 40 or the inner oriented surfaces of layers 10 c and 10 d of the film 10 a can also be rough or uneven. Further, the starting gauge 42, 42 a, and 42 b need not be consistent or uniform throughout the entirety of pre-stretched film 10 a. Thus, the starting gauge 42, 42 a, and 42 b can vary due to product design, manufacturing defects, tolerances, or other processing issues. According to one embodiment, the individual layers 10 c and 10 d may be pre-stretched (e.g., through MD ring rolling, TD ring rolling, etc.) before being positioned adjacent to the other layer (10 d or 10 c, respectively). Such pre-stretching of individual layers can result in a striped surface exhibiting an uneven top and bottom surface similar to that seen in FIG. 1A.

FIG. 1B illustrates that films 10 a, can include two initially separate film layers 10 c-10 d. FIG. 1C illustrates an alternative implementation where film 10 a′ (and thus the incrementally stretched film 10 i) can include three initially separate film layers: a middle film layer 10 g, and two outer film layers 10 f, 10 h. In other embodiments, more than 3 layers may be provided (four, five, six, or more partially discontinuously or discontinuously laminated layers).

As seen in FIG. 1A, upon stretching and partially discontinuous lamination of the adjacent layers, the multi-layered lightly-laminated film 10 b of FIG. 1A, 10 e of FIG. 1B, or film 10 i of FIG. 1C can include a striped pattern 36. The striped pattern 36 can include alternating series of un-bonded and un-stretched regions 44 adjacent to bonded and stretched regions 46. FIGS. 1B and 1C illustrate that the intermeshing rollers 12, 14 can incrementally stretch and partially discontinuously bond films 10 a, 10 a′ to create multi-layered lightly-laminated multi-layer films 10 b, 10 e, 10i including bonded regions 46 and un-bonded regions 44.

For example, FIG. 1B illustrates that the film layers 11 a, 11 b of the multi-layered lightly-laminated film 10 e can be laminated together at the stretched regions 46, while the un-stretched regions 44 may not be laminated together. Similarly, FIG. 1C illustrates that the film layers 11 c, 11 d, 11 e of the multi-layered lightly-laminated 10 i can be laminated together at the stretched regions 46, while the un-stretched regions 44 may not be laminated together.

In addition to any compositional differences between layers 10 c, 10 d, 10 f, 10 g, or 10 h of a given multi-layer film, the different film layers can have differing gauges or thicknesses. In one or more implementations, the film layers may be substantially equal to one another in thickness. For example, the inventors have found that the MD or TD tear resistance of the composite, multi-layer film is typically approximately equal to the lowest MD or TD tear value of the individual layers, absent any increase in tear resistance provided by light bonding. In other words, the weakest layer often determines the strength of the multi-layer film structure.

As shown by FIGS. 1B and 1C the un-bonded regions 44 of the multi-layered lightly-laminated films 10 e, 10 i, can have a first average thickness or gauge 48 a, 48 b, respectively. The first average gauge 48 a, 48 b can be approximately equal to the combined starting gauges 42 a-b, 42 c-e of the starting films. In the Figures, separation between the unbonded layers at regions 44 is exaggerated for purposes of clarity. In one or more implementations, the first average gauge 48 a, 48 b can be less than the combined starting gauges 42 a-42 b, 42 c-42 e. The lightly bonded regions 46 can have a second average thickness or gauge 50 a, 50 b. In one or more implementations, the second average gauge 50 a, 50 b can be less than the combined starting gauges 42 a-42 b, 42 c-42 e and the first average gauge 48 a, 48 b, respectively.

In any event, FIGS. 1A-1C illustrate that intermeshing rollers 12, 14 can process the initially separately layered films into MD incrementally-stretched multi-layered lightly-laminated films. As previously mentioned, the MD incrementally-stretched multi-layered lightly-laminated films can include a striped pattern 36 where the bonding occurs along a continuous line or region along the width of the film 10 b, parallel to the TD direction. The striped pattern 36 can include alternating series of un-bonded, un-stretched regions 44 and bonded, stretched regions 46. Although the un-stretched regions of the multi-layered lightly-laminated films may be stretched to a small degree by rollers 12, 14 (or stretched in a separate operation), the un-stretched regions may be stretched less compared to the bonded, stretched regions 46.

FIG. 2 illustrates a top view of the MD incrementally-stretched multi-layered lightly-laminated film 10 b with adjacent bonded and unbonded regions. As shown by FIG. 2, the film 10 b includes bonded, stretched regions 46 adjacent to un-bonded, un-stretched regions 44. In addition to resulting in partially discontinuous lamination of adjacent layers, MD ring rolling the film 10 can increase or otherwise modify one or more of the tensile strength, tear resistance, impact resistance, or elasticity of the film 10 b, in addition to whatever additional strength is provided by the partially discontinuous, low strength bonds between adjacent layers of the film. Such bonds can be broken to absorb forces rather than such forces resulting in tearing of the film.

Furthermore, the bonded, stretched regions 46 can include bonded stripes that extend across the film 10 b in a direction transverse (i.e., transverse direction) to a direction in which the film was extruded (i.e., machine direction). As shown by FIG. 2, the bonded stripes or stretched regions 46 can extend across the entire length of the film 10 b. One will appreciate in light of the disclosure herein that the striped pattern 36 may vary depending on the method used to incrementally stretch and partially discontinuously bond adjacent layers of film 10. To the extent that MD or other ring rolling is used to lightly bond the film 10, the striped pattern 36 (e.g., width and spacing of the stripes or stretched regions 46) on the film 10 can depend on the pitch 32 of the ridges 24, 26, the DOE 34, and other factors. As regions 46 represent areas of the multi-layer film in which the adjacent layers are lightly bonded to one another, it will be apparent that altering the spacing and/or width of regions 46 can affect the overall strength of the film. For example, providing more bonded surface area relative to the unbonded surface area can increase the density of such bonds that can absorb forces, increasing the film strength.

FIG. 2 further illustrates that the bonded regions 46 can be intermittently dispersed about un-bonded regions 44. In particular, each bonded region 46 can reside between adjacent un-bonded regions 44. Additionally, the bonded regions 46 can be visually distinct from the un-bonded regions 44 as a result of stretching. The striped pattern 36 may vary depending on the method used to lightly laminate the film 10. In one or more implementations, the molecular structure of the thermoplastic material of the film multi-layered 10 may be rearranged during stretching (e.g., particularly so during cold stretching).

MD ring rolling is one exemplary method of partially discontinuously laminating a multi-layer film by incremental stretching of the film. TD ring rolling is another suitable method of discontinuously or partially discontinuously laminating a film. For example, FIG. 3 illustrates a TD ring rolling process that partially discontinuously and lightly bonds adjacent layers of a thermoplastic multi-layer film 10 by passing the film 10 through a pair of TD intermeshing rollers 52, 54.

A TD ring rolling process (and associated TD intermeshing rollers 52, 54) can be similar to the MD ring rolling process (and associated MD intermeshing rollers 12, 14) described herein above, except that the ridges 56, 58 and grooves 60, 62 of the TD intermeshing rollers 52, 54 extend generally orthogonally to the axes of rotation 16, 20 (i.e., parallel to the MD direction). Thus, as shown by FIG. 3, as the thermoplastic film 10 passes between the intermeshing rollers 52, 54, the ridges 56, 58 can incrementally stretch and lightly bond adjacent layers of the multi-layer film 10. The resultant multi-layered lightly-laminated film 10 j can include a striped pattern 36 a with adjacent bonded and unbonded regions.

FIG. 4 illustrates a view of the TD incrementally-stretched multi-layered lightly-laminated film 10 j with bonded regions 46 a and adjacent un-bonded regions 44 a. The striped pattern 36 a can include alternating series of un-bonded regions 44 a and bonded regions 46 a. Similar to MD ring rolling, TD ring rolling the multi-layered film 10 can result in relatively light, partially discontinuous bonding of adjacent layers 10 c, 10 d (or 10 f, 10 g, 10 h), increasing the strength of the multi-layer film 10 j.

FIG. 4 illustrates that the bonded regions 46 a can include stripes that extend across the multi-layered lightly-laminated film 10 j in the machine direction. As shown by FIG. 4, the stripes or bonded regions 46 a can extend across the entire width of the multi-layered lightly-laminated film 10 j. In alternative implementations, bonded regions 46 a can extend across only a portion of the multi-layered lightly-laminated film 10 j. Similar to MD ring rolling, the pitch and the DOE of the ridges 56, 58 of the intermeshing rollers 52, 54 can affect the width and spacing of the stripes or bonded regions 46 a, as well as the strength of the light bonds formed between adjacent layers, thereby affecting the overall increase in strength provided by the processing.

In still further implementations, a multi-layered film 10 can undergo both an MD ring rolling process and a TD ring rolling process to lightly bond the individual layers together. For example, FIG. 5 illustrates a top view of a multi-layered lightly-laminated film 10 k with bonded, stretched regions separated by un-bonded, un-stretched regions created by MD and TD ring rolling. The multi-layered lightly-laminated film 10 k can have a grid pattern 36 b including alternating series of un-bonded regions 44 b and bonded regions 46 b, 46 c. In particular, un-bonded regions 44 b may comprise a plurality of discrete squares or rectangles while the remainder of the surface comprises a grid of horizontal and vertical bonded regions that are connected together. The bonded regions 46 b, 46 c can include stripes 46 b that extend along the multi-layered lightly-laminated film 10 k in the machine direction, and stripes 46 c that extend along the film in the transverse direction, which cross each other. As shown by FIG. 5, in one or more implementations, the aspect ratio of the rows and columns of the bonded regions 46 b, 46 c can be approximately 1 to 1. In alternative implementations, the aspect ratio of the rows and columns of bonded regions 46 b, 46 c can be greater or less than 1 to 1, for example, as explained in greater detail in relation to FIG. 13.

The multi-layered lightly-laminated film 10 k with bonded regions and adjacent un-bonded regions created by MD and TD ring rolling can allow for greater material savings by further increasing the surface area of a given portion of film, by increasing the density of light lamination bonds within a given area, and may also provide properties or advantages not obtained by MD or TD ring rolling alone.

In yet further implementations, a manufacturer can use DD ring rolling to lightly bond a thermoplastic film. DD ring rolling processes (and associated DD intermeshing rollers) can be similar to the MD ring rolling process (and associated MD intermeshing rollers 12, 14) described herein above, except that the ridges and grooves of the DD intermeshing rollers can extend at an angle relative to the axes of rotation. For example, FIG. 6 illustrates a view of multi-layered lightly-laminated film 101 with bonded regions created by DD ring rolling. The multi-layered lightly-laminated film 101 can have a diamond pattern 36 c. The diamond pattern 36 c can include alternating series of diamond-shaped un-bonded regions 44 c and bonded regions 46 d. The bonded regions can include stripes 46 d oriented at an angle relative to the transverse direction such that the stripes 46 d are neither parallel to the transverse or machine direction. The illustrated configuration may be achieved with two ring rolling operations, similar to that of FIG. 5, but in which the DD ring rollers of each operation are angularly offset relative to one another (e.g., one providing an angle of about 45° off of MD ring rolling, the other providing an angle of about 45° off of TD ring rolling).

In accordance with another implementation, a structural elastic like film (SELF) process may be used to create a thermoplastic film with strainable networks, which similarly results in discontinuous bonding of adjacent layers within a multi-layer film. As explained in greater detail below, the strainable networks can include adjacent bonded and un-bonded regions. U.S. Pat. No. 5,518,801; U.S. Pat. No. 6,139,185; U.S. Pat. No. 6,150,647; U.S. Pat. No. 6,394,651; U.S. Pat. No. 6,394,652; U.S. Pat. No. 6,513,975; U.S. Pat. No. 6,695,476; U.S. Patent Application Publication No. 2004/0134923; and U.S. Patent Application Publication No. 2006/0093766 each disclose processes for forming strainable networks or patterns of strainable networks suitable for use with implementations of the present invention. The contents of each of the aforementioned patents and publications are incorporated in their entirety by reference herein.

FIG. 7 illustrates a pair of SELF'ing intermeshing rollers 72, 74 for creating strainable networks with lightly bonded regions in a film. The first SELF'ing intermeshing roller 72 can include a plurality of ridges 76 and grooves 78 extending generally radially outward in a direction orthogonal to an axis of rotation 16. Thus, the first SELF'ing intermeshing roller 72 can be similar to a TD intermeshing roller 52, 54. The second SELF'ing intermeshing roller 74 can include also include a plurality of ridges 80 and grooves 82 extending generally radially outward in a direction orthogonal to an axis of rotation 20. As shown by FIG. 7, however, the ridges 80 of the second SELF'ing intermeshing roller 74 can include a plurality of notches 84 that define a plurality of spaced teeth 86.

Referring now to FIG. 8, a multi-layered lightly-laminated film 10 m with bonded regions dispersed about un-bonded regions created using the SELF'ing intermeshing rollers 72, 74 is shown. In particular, as the film passes through the SELF'ing intermeshing rollers 72, 74, the teeth 86 can press a portion of the multi-layer web or film out of plane to cause permanent deformation of a portion of the film in the Z-direction. The portions of the film that pass between the notched regions 84 of the teeth 86 will be substantially unformed in the Z-direction, resulting in a plurality of deformed, raised, rib-like elements 88. The length and width of rib-like elements 88 depends on the length and width of teeth 86.

As shown by FIG. 8, the strainable network of the multi-layered lightly-laminated film 10 m can include first un-bonded regions 44 d, second un-bonded regions 44 e, and bonded transitional regions 46 e connecting the first and second un-bonded regions 44 d, 44 e. The second un-bonded regions 44 e and the bonded regions 46 e can form the raised rib-like elements 88 of the strainable network. The bonded regions 46 e can be discontinuous or separated as they extend across the multi-layered film 10 m in both transverse and machine directions. This is in contrast to stripes that extend continuously across a film in one of the machine or transverse directions.

The rib-like elements 88 can allow the multi-layered lightly-laminated film 10 m to undergo a substantially “geometric deformation” prior to a “molecular-level deformation” or a “macro-level deformation.” As used herein, the term “molecular-level deformation” refers to deformation which occurs on a molecular level and is not discernible to the normal naked eye. That is, even though one may be able to discern the effect of molecular-level deformation, e.g., macro-level deformation of the film, one is not able to discern the deformation which allows or causes it to happen. As used herein, the term “macro-level deformation” refers to the effects of “molecular-level deformation,” such as stretching, tearing, puncturing, etc. In contrast, the term “geometric deformation,” which refers to deformations of multi-layered lightly-laminated film 10 m which are generally discernible to the normal naked eye, but do not cause the molecular-level deformation when the multi-layered film 10 m or articles embodying the multi-layered lightly-laminated film 10 m are subjected to an applied strain. Types of geometric deformation include, but are not limited to bending, unfolding, and rotating.

Thus, upon application of strain, the rib-like elements 88 can undergo geometric deformation before either the rib-like elements 88 or the flat regions undergo molecular-level deformation. For example, an applied strain can pull the rib-like elements 88 back into plane with the flat regions prior to any molecular-level deformation of the multi-layered film 10 m. Geometric deformation can result in significantly less resistive forces to an applied strain than that exhibited by molecular-level deformation.

In addition to improved properties thus provided by the ability to geometrically deform, the SELF'ing process also discontinuously and lightly laminates adjacent layers of the multi-layer film together, providing the benefits noted above. In particularly, the film layers 11 f, 11 g can be lightly laminated at stretched regions 46 e, but un-bonded at the un-stretched regions 44 d and 44 e. The strength of the lamination bond is relatively weak, so as to be less than the weakest tear resistance of the individual layers of the multi-layer film. Thus, the lamination bond is broken rather than the individual layer tearing upon application of a force. Typically, tearing in the MD direction requires less applied force than tearing in the TD direction, thus in one embodiment, the lamination bond strength is less than the MD tear resistance of each individual layer of the multi-layer film.

FIG. 9 illustrates a multi-layered lightly-laminated film 10 n with a strainable network of rib-like elements 88 a arranged in diamond patterns. The strainable network of the multi-layered lightly-laminated film 10 n can include first un-bonded regions 44 d, second un-bonded regions 44 e, and bonded transitional regions 46 e connecting the first and second un-bonded regions 44 d, 44 e.

One or more implementations of the present invention can include strainable network patterns other than those shown by FIGS. 8 and 9, or combinations of various patterns. It should be understood that the term “pattern” is intended to include continuous or discontinuous sections of patterns, such as may result, for example, from the intersection of first and second patterns with each other. Furthermore, the patterns can be aligned in columns and rows aligned in the machine direction, the transverse direction, or neither the machine or transverse directions.

For example, FIGS. 10A and 10B show a multi-layered lightly-laminated film 10 o where the film layers have undergone a film stretching process in which a discontinuous laminate material is formed with a strainable network of distinct regions. The strainable network laminate includes a plurality of un-bonded areas 146 that define a first region and a plurality of bonded areas 148 that define a second region. Portions of the un-bonded areas 146, indicated generally as 147, extend in a first direction and may be substantially linear. Remaining portions of the unbonded areas 146, indicated generally as 145, extend in a second direction that is substantially perpendicular to the first direction, and the remaining portions 145 of the unbonded areas 146 may be substantially linear. While it may be preferred that the first direction be perpendicular to the second direction, other angular relationships between the first direction and the second direction may be suitable. The angles between the first and second directions may range from about 45° to about 135°, with 90° being the most preferred. Intersecting sections of the portions 147 and 145 of the unbonded areas 146 form boundaries 150 (only one shown in FIG. 10A), which completely surround the bonded areas 148. It should be understood that the boundaries 150 are not limited to the square shape illustrated herein and that boundaries 150 may comprise other shapes as required by the particular configuration of the un-bonded and bonded areas 146, 148, respectively.

The multi-layered lightly-laminated multi-layer film 10o shown in FIG. 10A-10B comprises a multi-directional strainable network laminate providing stretch characteristics in multiple directions of strain, similar to that shown in FIG. 8. A first region comprises un-bonded areas 146 generally illustrated as bands of unformed material generally lying in a plane defined by the discontinuous laminate material 10 o. A second region comprises bonded areas 148 generally defined by nub-like patterns 152 (see FIG. 10B) extending out of the plane of the discontinuous laminate material 10 o and comprised of a pattern extending in first and second distinct directions as formed by first and second superimposed patterns, where the patterns are illustrated as being substantially similar to each other.

FIGS. 11A-11B illustrate an embossing type roll configuration for lightly bonding layers together by forming a multi-directional strainable network laminate in a single pass through a set of intermeshing rollers including a punch roll 153 and a cooperating die roll 154, where the punch roll is provided with punch regions 156 and the die roll is provided with corresponding die regions 158 for cooperating with the punch regions 156. The punch regions 156 may each be provided with a plurality of punch elements 160 for cooperating with corresponding die elements 162 in the die regions 158. Cooperating engagement of the punch elements 160 with the die elements 162, with a sheet material therebetween, forms a bonded pattern on the material. Alternatively, the cooperating die roll 154 may comprise a conformable surface for conforming to the punch elements 160, or other surface configuration of the punch roll 153.

Referring to FIG. 11C, a pattern formed by the rolls 153, 154 is illustrated in which each of the bonded areas 148 of the multi-directional strainable network laminate is formed by a cooperating set of punch and die elements 160, 162, such as is illustrated in the enlarged surface views of FIG. 22B, and the remaining unformed areas define the un-bonded areas 146 of the multi-layered lightly-laminated film including multi-directional strainable networks.

One will appreciate in light of the disclosure herein that using ring rolling and/or SELFing to form the light bonds can provide the additional benefit of stretching the film layers, thereby reducing the basis weight of the multi-layered lightly-laminated film. Thus, using incremental stretching to form the light bonds can allow for multi-layer films at a lower basis weight (amount of raw material) to perform the same as or better than higher basis weight mono-layer or co-extruded films.

In addition to ring rolling and SELFing, one or more implementations include using embossing, stamping, adhesive lamination, ultrasonic bonding, or other methods of lightly laminating layers of a multilayer film. In such implementations, one or more of the layers of the multi-layered lightly-laminated film can be stretched to reduce the basis weight and/or modify the strength parameters of the film prior to lamination. Stretching of the individual layers can include incrementally-stretching (e.g., ring rolling, SELFing) or continuous stretching (e.g., MDO).

One will appreciate in light of the disclosure herein that the lightly bonded multi-layered films can form part of any type of product made from, or incorporating, thermoplastic films. For instance, grocery bags, trash bags, sacks, packaging materials, feminine hygiene products, baby diapers, adult incontinence products, sanitary napkins, bandages, food storage bags, food storage containers, thermal heat wraps, facial masks, wipes, hard surface cleaners, and many other products can include lightly bonded multi-layer films to one extent or another. Trash bags and food storage bags may be particularly benefited by the films and methods of the present invention.

Referring to FIGS. 12A and 12B, a flexible draw tape multi-layered bag 90 of one or more implementations of the present invention is shown. The multi-layered bag 90 can include a bag body 92 formed from two pieces of thermoplastic film 10 p and 10 q folded along a bag bottom 94. Side seams 96 and 98 can bond the sides of the bag body 92 together to form a semi-enclosed container having an opening 100 along an upper edge 102. The multi-layered bag 90 also optionally includes closure means 104 located adjacent to the upper edge 102 for sealing the top of the multi-layered bag 90 to form a fully-enclosed container or vessel. The multi-layered bag 90 is suitable for containing and protecting a wide variety of materials and/or objects. In alternative implementations, in place of a draw tape, the closure means 104 can comprise flaps, adhesive tapes, a tuck and fold closure, an interlocking closure, a slider closure, a zipper closure or other closure structures known to those skilled in the art for closing a bag.

As shown by FIGS. 12A and 12B, the multi-layered bag 90 can have a first layer of thermoplastic material (i.e., film 10 p). The first layer (i.e., film 10 p) can include first and second side walls joined along a bottom edge, a first side edge, and an opposing second side edge. In particular, the bottom edge of the first layer (i.e., film 10 p) can comprise a fold. The multi-layered bag 90 can also include a second layer of thermoplastic material (i.e., film 10 q). The second layer (i.e., film 10 q) can include first and second side walls joined along a bottom edge, a first side edge, and an opposing second side edge.

As shown by FIG. 12B, the second layer (i.e., film 10 q) is positioned within the first layer (i.e., film 10 p). Furthermore, the first layer (i.e., film 10 p) and the second layer (i.e., film 10 q) are non-continuously bonded to each other as described below. Furthermore, in the implementation shown in FIGS. 12A and 12B, both the first layer (i.e., film 10 p) and the second layer (i.e., film 10 q) are incrementally stretched.

Such a configuration may be considered a “bag-in-bag” configuration. In other words the multi-layered bag 90 can include a second thermoplastic bag 10 q positioned within a first thermoplastic bag 10 p. Each of the first and second bags 10 p, 10 q can include a first pair of opposing sidewalls joined together along three edges. A plurality of non-continuous bonded regions can secure the first and second thermoplastic bags together.

In particular as shown by FIG. 12A, the multi-layered bag 90 can include discrete zones of non-continuous lamination between the layers 10 p, 10 q. In particular, the multi-layered bag 90 includes a first, top section 116 that is adjacent the opening 100 and a second, bottom section 120 that is adjacent the bottom edge or fold 94. The top section 116 of the multi-layered bag 90 can include bonded regions interspersed with un-bonded regions. In particular, FIG. 12A illustrates that the top section 116 can include strainable network bonds 101 (i.e., bonds created by a SELFing process) arranged in diamond patterns similar to the multi-layered lightly-laminated film 10 n of FIG. 9. The strainable network bonds 101 can discontinuously bond the layers 10 p and 10 q together in the top section 116.

The bottom section 120 on the other hand can include non-continuous bonds 46 a created by TD ring rolling. In particular, the bottom section 120 can include un-bonded regions 44 a and bonded regions 46 a in the form of stripes. The stripes can extend across the multi-layered bag 90 in the MD direction, or in other words, from the first side seam 96 to the second side seam 98.

One will appreciate in light of the disclosure herein that the different types of non-continuous bonds in the top and bottom sections 116, 120 can provide the different strength and aesthetic properties to the top and bottom sections 116, 120. For example, the non-continuous bonds 46 a created by TD ring rolling can provide the bottom section 120 with increased MD tear resistance, balanced MD and TD resistances, and/or increased the impact and/or puncture resistance. Additionally, the TD ring rolling of the bottom section 120 can result in reduced material utilization. The strainable network bonds 101 can provide the top section 116 with the ability to stretch around objects and prevent tears and rips. In other implementations, the inner and outer bags can be non-continuously laminated together through the use of TD ring rolling, DD, ring rolling, SELFing, ultrasonic bonding, adhesive bonding, or any combination of such various bonding techniques.

Thus, one or more implementations allow for the tailoring of various zones or sections of a multi-layered bag with different non-continuous bonds or bonded regions. In particular, different types, sizes, shapes, patterns, concentrations, and/or combinations of non-continuous bonds can provide different zones or sections of a multi-layered bag with strength and/or aesthetic properties optimal for the particular zone or section. FIG. 12A illustrates a multi-layered bag 90 with two zones. One will appreciate that the present invention is not so limited and multi-layered bags of one or more implementations can include 2, 3, 4, 5, 6, or more zones or sections with tailored non-continuous bonds. Furthermore, the Figs. illustrate sections that extend along the width of the bag (i.e., bottom, middle, and upper), in alternative implementations, the sections can extend across the height of the bag (i.e., left side, middle, right side). In still further implementations the sections can comprise a combination of width-wise and length-wise extending sections. Alternatively, the sections are neither width-wise nor length-wise extending. For example, the sections can extend at an angle to the edges of the bag.

FIG. 13 illustrates a multi-layered tie bag 106 with discrete non-continuous lamination in accordance with an implementation of the present invention. In particular, the multi-layered tie bag 106 includes an outer film 10 r non-continuously bonded to an inner film 10 s in discrete sections or zones. In particular, a plurality of strainable network bonds 101 can non-continuously bond the outer film 10 r to the inner film 10 s in the bottom section 120. On the other hand, a plurality of non-continuous bonds 46 f formed from TD ring rolling can non-continuously bond the outer film 10 r to the inner film 10 s in the upper section 116.

The bonded regions 46 f and 101 are characterized by relatively light bonding of adjacent layers 10 r, 10 q of the multi-layer bag 106, which acts to absorb forces into breaking of the lamination bond rather than allowing that same force to cause tearing of either of the layers of the multi-layer bag 106. Such action provides significantly increased strength to the multi-layer film as compared to a monolayer similar thickness film or compared to a multi-layer film of similar thickness where the layers are strongly bonded together (i.e., at a bond strength at least as great as the tear resistance of the weakest layer). The lamination bond includes a bond strength that is advantageously less than the tear resistance of each of the individual films so as to cause the lamination bond to fail prior to tearing of the film layers.

In addition to non-continuous bonding, one or more layers of the multi-layered bags of one or more implementations can be incrementally stretched. One will appreciate that some types of non-continuous bonding described here can incrementally stretch the layers as they are non-continuously bonded (i.e., ring rolling, SELFing). One or more implementations of the present invention further include incrementally stretching one or more layers independent of bonding. For example, the outer layer 10 r of the multi-layer bag 106 of FIG. 13 is a MD incrementally stretched film, similar to film 10 b of FIG. 2. The MD incrementally stretched film 10 r is then non-continuously laminated to the inner layer 10 s as described above.

In comparison with the film 10 k of FIG. 5, the spacing between the MD extending bonds 46 f is greater in the multi-layered bag 106. This effect is created by using TD ring rolls having a greater pitch between ridges. Similarly, the spacing of the TD extending stripes 46 g is greater in the multi-layered bag 106 than the multi-layered film 10 m. This effect is created by using TD ring rolls having a greater pitch between ridges. Furthermore, the relative spacing between the MD extending stripes and the TD extending stripes differs in the multi-layered bag 106, while relative spacing is the same in the multi-layered film 10 k. This effect is created by using TD ring rolls having a greater pitch between ridges compared to the pitch between ridges of the MD ring rolls.

One will appreciate in light of the disclosure herein that the use of intermeshing rollers with greater or varied ridge pitch can provide the different spacing and thicknesses of the stripes. Thus, a manufacturer can vary the ridge pitch of the intermeshing rollers to vary the pattern of the multi-layer film. The bond density (i.e., the fraction of surface area that is bonded relative to unbonded) and particular pattern provided not only affects the aesthetic appearance of the bag or film, but may also affect the strength characteristics provided. For example, higher bond density may provide increased strength as it provides a greater number of relatively low strength lamination bonds that may be broken so as to absorb forces, preventing such forces from leading to tearing of the bag or film. Film 10 k of FIG. 5 has a higher bond density than the film of the bag 106 of FIG. 13.

By way of further example, where the MD tear resistance is lower than TD tear resistance for the particular films employed, it may be advantageous to provide a higher density of bonds in the MD than the TD direction. This may provide greater improvement to MD tear resistance of the multi-layered lightly-laminated film as compared to TD tear resistance improvement. A similar configuration could be provided for films in which the TD tear resistance were lower than MD tear resistance by increasing bond density in the TD direction.

In addition to varying the pattern of bonded and un-bonded regions in a bag or film, one or more implementations also include providing lightly bonded regions in certain sections of a bag or film, and only un-bonded (or alternatively tightly bonded) regions in other sections of the bag or film. For example, FIG. 14 illustrates a multi-layered bag 114 having an upper section 116 adjacent a top edge 118 that is devoid of bonded regions. Similarly, the multi-layered bag 114 includes a bottom section 120 adjacent a bottom fold or edge 122 devoid of bonded regions. In other words, both the top section 116 and bottom section 120 of the multi-layered bag 114 can each consist only of un-bonded regions. Alternatively, the layers of sections 116 and 120 may be tightly bonded together (e.g., co-extruded). In any case, sections 116 and 120 may be void of bonds.

A middle section 124 of the multi-layered bag 114 between the upper and lower sections 116, 120 on the other hand can include lightly bonded regions interspersed with un-bonded regions. In particular, FIG. 14 illustrates that the middle section can include a strainable network of rib-like elements arranged in diamond patterns similar to the multi-layered lightly-laminated film 10 n of FIG. 9. Thus, the middle section 124 of the multi-layered bag 114 can include improved strength created by the light bonds of the strainable network.

As mentioned previously, one or more implementations of the present invention includes providing different lightly bonded regions in different sections of a bag or film. For example, FIG. 15 illustrates a multi-layered bag 114 a similar to the multi-layered bag 114 of FIG. 14, except that the bottom section 120 a includes alternating series of un-bonded regions 44 a and bonded regions 46 a created by TD ring rolling. Thus, the middle section 124 of the bag 114 can include properties of increased strength as a result of light discontinuous lamination and increased elasticity through geometric deformation, while the bottom section includes increased strength as a result of light partially discontinuous lamination by TD ring rolling.

FIG. 16 illustrates yet another multi-layered bag 126 including an upper section 116 a adjacent a top edge 118 that includes alternating series of un-bonded regions 44 b and bonded regions 46 b, 46 c created by MD and TD ring rolling similar to the film 10 k of FIG. 5. Furthermore, the middle section 124 a of the multi-layered bag 126 can include un-bonded regions 44 and bonded regions 46 in the form of stripes created by MD ring rolling.

Thus, one will appreciate in light of the disclosure herein that a manufacturer can tailor specific sections or zones of a bag or film with desirable properties by MD, TD, DD ring rolling, SELF'ing, or combinations thereof. One will appreciate in light of the disclosure herein that one or more implementations can include bonded regions arranged in other patterns/shapes. Such additional patterns include, but are not limited to, intermeshing circles, squares, diamonds, hexagons, or other polygons and shapes. Additionally, one or more implementations can include bonded regions arranged in patterns that are combinations of the illustrated and described patterns/shapes.

FIGS. 17-25 illustrate additional exemplary implementations of multi-layer bags that may be formed from multi-layered lightly-laminated films. FIGS. 17-19 and 25 illustrate additional examples of bags 127 including squares 128, diamonds 130, and circles 132 representing the bonded areas of the two or more adjacent layers. In one or more implementations, such as FIGS. 17-18 and 23, each bonded pattern may have a largest TD patterned width 134 in the transverse direction (TD) of less than about 25% of the transverse width 136 of the patterned film, or less than about 20% of the transverse width of the film, or less than about 10% of the transverse width of the patterned film, or less than about 5% of the transverse width of the film. In one or more implementations, the bonded patterns should have a largest MD patterned width 138 in the machine direction of less than about 25% of the machine width 140 of the patterned film, or less than about 20% of the machine width of the film, or less than about 10% of the machine width of the film, or less than about 5% of the transverse width of the film.

In one or more implementations, the width 134 of the bonded patterns in the transverse direction may be greater than the width 142 of the un-bonded areas in the transverse direction. The width 138 of the bonded patterns in the machine direction or direction perpendicular to the transverse direction may be greater than the width of the un-bonded areas 144 in the machine direction.

The bond density of the multi-layered lightly-laminated films and bags incorporating the same can be varied to control the bond strength between the layers. For example, bonded areas of multi-layered lightly-laminated films and bags incorporating the same can be large in comparison to un-bonded areas, as seen in the implementations of FIGS. 17-18 and 25. For example, bonded areas of multi-layered lightly-laminated films and bags incorporating the same can represent at least about 50% of the total area of the entire film, the entire bag, or the section where the lamination occurs, or at least about 60% of the entire film, the entire bag, or total area of the section where the lamination occurs, at least about 70% of the entire film, the entire bag, or total area of the section where the lamination occurs, at least about 80% of the total area of the entire film, the entire bag, or section where the lamination occurs. In other embodiments, for example in FIGS. 19-20, the bonded areas of multi-layered lightly-laminated films and bags incorporating the same can represent substantially less than about 50% of the total area of the entire film, the entire bag, or section where the lamination occurs, or less than about 40% of the total area of the entire film, the entire bag, or section where the lamination occurs, or less than about 30% of the total area of the entire film, the entire bag, or section where the lamination occurs, or less than about 10% of the total area of the entire film, the entire bag, or section where the lamination occurs.

As mentioned previously, numerous methods can be used to provide the desired degree of lamination in the bonded areas. Any of the described ring rolling techniques may be combined with other techniques in order to further increase the strength of the lamination bond while maintaining bond strength below the strength of the weakest layer of the multi-layer film. For example, heat, pressure, ultrasonic bonding, corona treatment, or coating (e.g., printing) with adhesives may be employed. Treatment with a corona discharge can enhance any of the above methods by increasing the tackiness of the film surface so as to provide a stronger lamination bond, but which is still weaker than the tear resistance of the individual layers.

Adjusting (e.g., increasing) the strength of the relatively light lamination bonding could be achieved by addition of a tackifier or adhesive to one or more of the skin plies of a multi-layer film, or by incorporating such a component into the material from which the film layer is formed. For example, the outer skin sublayers of a given layer could contain from about 0 to about 50% of a polyolefin plastomer tackifier such as a C₄-C₁₀ olefin to adjust bonding strength by increasing the tackiness of the surfaces of adjacent layers to be lightly laminated.

In one or more implementations, a component may be included to decrease tackiness. For example, the outer skin sublayers could contain higher levels of slip or anti-block agents, such as talc or oleamide (amide of oleic acid), to decrease tack. Similarly, these surfaces may include very low levels of or be substantially void of slip or anti-block agents to provide a relative increase in tackiness.

FIG. 18 shows a multi-layer bag 127 including a top section that has been both MD and TD ring rolled, while the bottom section has not been discontinuously laminated. FIG. 19 shows a bag 127 including a relatively low density of bonded circles 132 arranged over substantially the entire surface of bag 127. FIG. 20 shows a bag 127 including an even lower density of bonded diamonds near top and bottom sections of bag 127. FIG. 21 shows a multi-layer bag 127 that has been ring rolled near the top and bottom of the bag. The middle section of the bag represents an un-bonded region between the ring top and bottom portions of bag 127. FIG. 22 shows a bag 127 similar to that of FIG. 21 but in which the bottom section is un-bonded. FIG. 23 shows a bag 127 similar to that of FIG. 21, but in which the top section includes squares of bonded regions rather than being ring rolled. FIG. 24 is similar to the bag of FIG. 20, but in which the bonded ring rolled portions along the top are discontinuous. FIG. 25 shows a multi-layer bag 127 including top and bottom sections that have been DD ring rolled, while a middle section therebetween has not been discontinuously laminated

In another implementation, a pattern may be formed by embossing, in a process similar to ring rolling. Embossed patterns such as squares, diamonds, circles or other shapes may be embossed into a multi-layer film such as shown in FIGS. 17-20, and 25. The embossed, laminated film layers may be prepared by any suitable means by utilizing two or more layers of preformed web of film and passing them between embossing rollers. The method of embossing multiple layers of film can involve calendar embossing two or more separate, non-laminated layers with discrete “icons” to form bonded areas or icons, each icon having a bonded length and separated from adjacent icons by an equivalent un-bonded length. Such icons may be any desired design or shape, such as a heart, square, triangle, diamond, trapezoid, or circle. In FIG. 18, the embossed icons are squares.

Implementations of the present invention can also include methods of forming multi-layered lightly-laminated film and bags including the same. FIGS. 26-28 and the accompanying description describe such methods. Of course, as a preliminary matter, one of ordinary skill in the art will recognize that the methods explained in detail herein can be modified. For example, various acts of the method described can be omitted or expanded, additional acts can be included, and the order of the various acts of the method described can be altered as desired.

FIG. 26 illustrates an exemplary embodiment of a high-speed manufacturing process 164 for creating multi-layered thermoplastic film(s) with discrete non-continuous lamination and then producing multi-layered plastic bags with discrete non-continuous lamination therefrom. According to the process 164, a first thermoplastic film layer 10 c and a second thermoplastic film layer 10 d are unwound from roll 165 a and 165 b, respectively, and directed along a machine direction.

The film layers 10 c, 10 d may pass between first and second cylindrical intermeshing rollers 166, 167 to incrementally stretch and lightly laminate the initially separate film layers 10 c, 10 d to create un-bonded regions and bonded regions in a middle section of a multi-layered discretely laminated film 168. As shown in FIG. 26, the intermeshing rollers 166, 167 can be TD intermeshing rollers similar to the intermeshing rollers 52, 54 of FIG. 3. Alternatively, the intermeshing rollers 166, 167 can comprise embossing or SELFing rollers. In still further implementations, in place of the intermeshing rollers 166, 167 the process can include an adhesive applicator or ultrasonic horn that can form adhesive or ultrasonic bonds.

Returning to FIG. 26, the rollers 166, 167 may be arranged so that their longitudinal axes are perpendicular to the machine direction. Additionally, the rollers 166, 167 may rotate about their longitudinal axes in opposite rotational directions as described in conjunction with FIG. 1A. In various embodiments, motors may be provided that power rotation of the rollers 166, 167 in a controlled manner. As the film layers 10 c, 10 d pass between the first and second rollers 166, 167, the ridges and/or teeth of the intermeshing rollers 166, 167 can form a multi-layered discretely laminated film 168.

Optionally, the multi-layered discretely laminated film 168 may then pass through another lamination process to discretely, non-continuously laminate another section or zone of the multi-layered discretely laminated film 168 together. For example, FIG. 26 illustrates that the multi-layered discretely laminated film 168 can pass between another set of intermeshing rollers 194, 195. The intermeshing rollers 194, 195 can non-continuously laminate the one or additional sections of the multi-layered discretely laminated film 168 together. As shown in FIG. 26, the intermeshing rollers 194, 195 can comprise embossing rollers or alternatively any other of the intermeshing rollers described hereinabove. Alternatively, a single set of intermeshing rollers can laminate multiple sections of two or more films together. For example, the ridges and/or teeth of the intermeshing rollers 166, 167 and intermeshing rollers 194, 195 can be combined into a single set of intermeshing rollers that discretely laminate different sections of two or more films together using different types of bonding. In yet further implementations, an adhesive applicator or ultrasonic horn can be used in place of intermeshing rollers 194, 195 to create non-continuous bonds in one or more sections.

During the manufacturing process 164, the multi-layered discretely laminated film 168 can also pass through a pair of pinch rollers 169, 170. The pinch rollers 169, 170 can be appropriately arranged to grasp the multi-layered discretely laminated film 168.

A folding operation 171 can fold the multi-layered discretely laminated film 168 to produce the sidewalls of the finished bag. The folding operation 171 can fold the multi-layered discretely laminated film 168 in half along the transverse direction. In particular, the folding operation 171 can move a first edge 172 adjacent to the second edge 173, thereby creating a folded edge 174. The folding operation 171 thereby provides a first film half 175 and an adjacent second web half 176. The overall width 177 of the second film half 176 can be half the width 177 of the pre-folded multi-layered discretely laminated film 168.

To produce the finished bag, the processing equipment may further process the folded multi-layered discretely laminated film 168. In particular, a draw tape operation 178 can insert a draw tape 179 into ends 172, 173 of the multi-layered discretely laminated film 168. Furthermore, a sealing operation 180 can form the parallel side edges of the finished bag by forming heat seals 181 between adjacent portions of the folded multi-layered discretely laminated film 168. The heat seal 181 may strongly bond adjacent layers together in the location of the heat seal 181 so as to tightly seal the edges of the finished bag. The heat seals 181 may be spaced apart along the folded multi-layered discretely laminated film 168 to provide the desired width to the finished bags. The sealing operation 180 can form the heat seals 181 using a heating device, such as, a heated knife.

A perforating operation 182 may form a perforation 183 in the heat seals 181 using a perforating device, such as, a perforating knife The perforations 183 in conjunction with the folded outer edge 174 can define individual multi-layered bags with discrete non-continuous lamination 184 that may be separated from the multi-layered discretely laminated film 168. A roll 185 can wind the multi-layered discretely laminated film 168 embodying the finished bags 184 for packaging and distribution. For example, the roll 185 may be placed into a box or bag for sale to a customer.

In still further implementations, the folded multi-layered discretely laminated film 168 may be cut into individual bags along the heat seals 181 by a cutting operation. In another implementation, the folded multi-layered discretely laminated film 168 may be folded one or more times prior to the cutting operation. In yet another implementation, the side sealing operation 180 may be combined with the cutting and/or perforation operations 182.

One will appreciate in light of the disclosure herein that the process 164 described in conjunction with FIG. 26 can be modified to omit or expand acts, vary the order of the various acts, or otherwise alter the process, as desired. For example, three or more separate film layers can be discontinuously laminated together to form a multi-layered discretely laminated film 168 similar to that shown in FIG. 1C.

FIG. 27 illustrates another manufacturing process 186 for producing a plastic bag from a multi-layered discretely laminated film. The process 186 can be similar to process 164 of FIG. 26, except that the film layers 10 c, 10 d are folded in half to form c-, u-, or j-folded films prior to winding on the rolls 165 a, 165 b. Thus, in such implementations, the films 10 c, 10 d unwound from the rolls 165 a, 165 b are already folded.

Additionally, the manufacturing process 186 illustrates that each film 10 c, 10 d can pass through a set of intermeshing rollers 166 a, 167 a, 166 b, 166 b to incrementally stretch the films prior to bonding. The manufacturing process 186 can then include an insertion operation 187 for inserting the folded film 10 d into the folded film 10 c. Insertion operation 187 can combine and laminate the folded films 10 c, 10 d using any of the apparatus and methods described in U.S. patent application Ser. Nos. 13/225,930 filed Sep. 6, 2011 and entitled Apparatus For Inserting A First Folded Film Within A Second Folded Film and Ser. No. 13/225,757 filed Sep. 6, 2011 and entitled Method For Inserting A First Folded Film Within A Second Folded Film, each of which are incorporated herein by reference in their entirety.

Additionally, FIG. 27 illustrates that the film layers 10 c, 10 d can then pass through a lamination operation 188 to lightly bond or laminate the films 10 c, 10 d together. Lamination operation 188 can lightly laminate the folded films 10 c, 10 d together via adhesive bonding, pressure bonding, ultrasonic bonding, corona lamination, and the like. Alternatively, lamination operation can lightly laminate the folded films 10 c, 10 d together by passing them through machine-direction ring rolls, transverse-direction ring rolls, diagonal-direction ring rolls, SELF'ing rollers, embossing rollers, or other intermeshing rollers. Furthermore, the lamination operation 188 can laminate one or more sections of the film with a first plurality of non-continuous bonds and one or more additional sections with a second plurality of non-continuous bonds. The second plurality of non-continuous bonds can differ from the first plurality of non-continuous bonds.

FIG. 28 illustrates another manufacturing process 190 for producing a multi-layered lightly-laminated film and a multi-layered bag therefrom. The process 190 can be similar to process 164 of FIG. 25, except that each film layer 10 c and 10 d may be run through intermeshing rollers (e.g., MD ring rollers) 166, 167 and 166 a, 167 a, respectively, prior to discontinuous lamination of layers 10 c and 10 d to one another. Similar to process 164 of FIG. 25, layers 10 c and 10 d may then be non-continuously laminated together in discrete sections by passing through intermeshing rollers 192, 193.

I. EXAMPLES

Multi-layered lightly-laminated films according to the present invention were formed according to various ring rolling processes. Table I below lists various discontinuously laminated films and comparative films that were tested. Table II lists the physical properties of the films of Table I. The results recorded in Table II indicate that the bi-layer films that were lightly bonded together with discontinuous lamination exhibit significantly improved strength properties, such as the energy to maximum load (Dynatup Max), which relates to impact resistance. The melt index of the layers of the films were determined under ASTM D-1238, Condition E. It is measured at 190° C. and 2.16 kilograms and reported as grams per 10 minutes.

TABLE I Discontinuously Laminated Films Discontinuous Gauge Film Layer 1 Process Layer 2 Process Lamination (Mils) A LLDPE 0.40 B LDPE 0.40 C HDPE 0.40 D LLDPE Yes 0.40 E LDPE Yes 0.40 F HDPE Yes 0.40 G LLDPE LLDPE Yes 0.80 H LDPE LDPE Yes 0.80 I HDPE HDPE Yes 0.80 J LLDPE TD RR LDPE TD RR Yes 0.80 K LLDPE TD RR HDPE TD RR Yes 0.80 L LDPE TD RR HDPE TD RR Yes 0.80 M LLDPE MD RR LLDPE TD RR Yes 0.80 N LLDPE MD RR LDPE TD RR Yes 0.80 O LLDPE MD RR HDPE TD RR Yes 0.80 LLDPE has a density of 0.920 and a Melt Index of 1.000. LDPE has a density of 0.926 and a Melt Index of 0.800. HDPE has a density of 0.959 and a Melt Index of 0.057. TD RR is TD ring rolling at 40 Pitch. MD RR is MD ring rolling at 60 Pitch. Discontinuous Lamination was achieved through SELF'ing at a DOE of 0.038″.

TABLE II Physical Properties Tear Yield Peak Load Strain@Break DynatupEnergy Film MD TD MD TD MD TD MD TD to max. load A 165 274 0.66 0.64 3.44 1.59 532 606 3.10 B 72 283 0.81 0.86 3.72 2.28 482 660 0.25 C 3 314 1.74 0.86 3.83 0.89 268 135 N.A. D 181 176 0.55 0.60 1.21 1.44 352 557 3.20 E 175 197 0.70 0.75 1.46 1.21 331 473 1.71 F 12 170 0.30 3.13 1.70 0.70 115 64 0.45 G 372 427 1.12 1.25 2.92 2.59 389 551 5.81 H 312 375 1.39 1.54 2.83 2.39 346 518 3.60 I 14 220 1.20 0.44 2.71 1.07 112 78 0.87 J 392 385 1.21 1.40 3.19 2.71 385 540 4.15 K 191 292 1.75 1.27 2.62 1.53 61 535 3.32 L 158 288 2.20 1.50 3.00 1.55 252 498 2.63 M 539 368 1.26 1.26 3.32 3.06 456 401 7.19 N 544 383 1.27 1.69 2.18 2.91 365 362 6.96 O 574 189 1.44 3.87 1.74 3.87 404 157 1.41 Control 225 625 1.46 1.43 6.29 4.36 476 665 Tear in grams. Yield in Lb_(f) Peak Load in Lb_(f) Strain@Break in % Dynatup Energy to Max in In-Lb_(f) Control is 0.9 Mil LDPE film

As shown in Table III, another set of films was evaluated with different levels of stretch processes with and without discontinuous lamination of adjacent layers. The results show significantly increased values of Dynatup Energy to maximum load as a result of discontinuous lamination.

TABLE III Additional Examples Dynatup Gauge Gauge Layer 1 Layer 2 Discontinuous Energy to Initial Final Film Process Process Lamination max. load (mils) (mils) P None None Yes 18.3 2.14 2.12 Q MD-1 TD-1 No 7.2 2.14 1.92 R MD-1 TD-1 Yes 17.1 2.14 1.93 S MD-2 TD-2 No 8.7 2.14 1.68 T MD-2 TD-2 Yes 15.3 2.14 1.63 Base None None No 5 1.07 1.07

As shown in Table IV, samples of cold processed MD ring rolled (at 0.100″ DOE, 0.100″ pitch, LDPE film were laminated under a cold ring rolling process to achieve unexpectedly superior tear resistance properties. The MD Tear and the TD Tear resistance values were synergistically enhanced as a result of the discontinuous lamination process. Bond strength could be further increased while still being less than the strength of the weakest layer by addition of a tackifier, an adhesive, corona treatment, etc. to increase tackiness between the layers.

TABLE IV Ring Rolled Laminates Sample MD Tear TD Tear TD ring rolled laminate of A and B, 21.5 gsm^(a) 429 881 A. MD ring rolled, Black top layer^(b) 193 580 B. MD ring rolled, White bottom layer^(c) 261 603 TD ring rolled laminate of C and D, 18.8 gsm 314 876 C. MD ring rolled, Black top layer^(d) 170 392 D. MD ring rolled, Black bottom layer^(d) 151 470 TD ring rolled laminate of E and F, 21.1 gsm 312 1018 E. MD ring rolled, Black top layer^(b) 218 765 F. MD ring rolled, Black bottom layer^(d) 170 387 ^(a)TD ring rolling was 0.040″ pitch tooling run at 0.020″ DOE. The A and B webs were simultaneously run first through the MD and then the TD tooling. ^(b)14 gsm 3 ply coextruded black layer with outer skin plies containing 30% DOW Affinity ™ 8100 and 2% talc, processed at blowup ratio A and MD ring rolled. MD ring rolling was 0.100″ pitch tooling run at 0.100″ DOE. ^(c)14 gsm 3ply coextruded white layer with 2% slip agent in outer skin plies, processed at blowup ratio 1.5A and MD ring rolled at 0.100″ pitch tooling run at 0.100″ DOE. ^(d)14 gsm 3 ply coextruded black layer with outer skin plies containing 30% DOW Affinity ™ 8100 and 2% talc, processed at blowup ratio 1.5A and MD ring rolled at 0.100″ pitch tooling run at 0.100″ DOE.

The MD and TD tear values shown in Table IV show how the MD tear value is significantly increased relative to the MD tear value of the individual layers. The data shows an additive or synergistic effect in both MD and TD tear resistance. For example, Example A exhibits an MD tear resistance of 193 g-f, while Example B exhibits an MD tear resistance of 261 g-f. When both layers are lightly laminated together by TD ring rolling, the MD tear resistance is 429 g-f. This is nearly as great as the additive strength of the two layers, which would be 454 g-f. Such results are particularly surprising and advantageous, as when the two layers are tightly laminated together (e.g., co-extruded), the strength of the composite film typically reverts to the have a strength approximately equal to that of the weakest layer (i.e., about 193 g-f). Thus, the light, discontinuous lamination of adjacent layers into a multi-layer film provides significant increases in strength.

Examples A through F were each discontinuously laminated by MD ring rolling at a pitch of 0.100″, a DOE of 0.100″, and simultaneously TD ring rolling at a pitch of 0.040″ and a DOE of 0.020″.

In another example, a first layer of a base film having a core ply of LLDPE with white pigment and outer plies of LLDPE\LDPE\Antiblock blend was cold MD ring rolled to form an MD ring rolled (RR) film. The MD intermeshing rolls used in Example 1 had a 0.100″ pitch and were set at a DOE of 0.110″. A second layer of the base film was cold TD ring rolled to form a TD RR film. The TD intermeshing rolls used in Example 1 had a 0.060″ pitch and were set at a DOE of 0.032″. The MD RR film and the TD RR film were then laminated together using a butene-1-copolymer, hot melt adhesive, Rextac® RT 2730 at four different coat weights shown in Table V as samples 1-4. Table V also shows comparative properties of the base film, the MD RR film, the TD RR film, the combined MD RR and TD RR films not adhesively laminated together, as well as a thicker film.

TABLE V Dynatup and Tear Resistance of Incrementally-Stretched Adhesively- Laminated Films (1 layer MD RR and 1 layer TD RR) Coat Dynatup Dynatup Weight Gage Tensile Peak Energy to MD TD g/sq. by Wt. Peel Load max load Tear Tear ft. (mils) (g-f) (lb-f) (in. lb-f) (g) (g) Sample 1 0.225 0.84 N/A 11.3 8.4 434 585 Sample 2 0.056 0.84 N/A 11.1 11.2 496 539 Sample 3 0.015 0.84 61 10.5 9.2 387 595 Sample 4 0.012 0.84 57 11.3 10.4 425 643 Comparison Data Un-laminated NA 0.84 N/A 9.4 6.9 326 502 Combined MD and TD RR Films TD RR Film NA 0.4 N/A 4.6 4.4 101 60 MD RR Film NA 0.44 N/A 5.4 4.8 173 475 Base Film NA 0.6 N/A 5.1 6.3 298 473 Thicker Base NA 0.9 NA 4.3 3.8 262 843 Film

The results from Table V show that even with very low adhesive coating, superior Dynatup, MD tear resistance, and TD tear resistance properties are achieved compared to two layers of non-laminated film or one layer of thicker film. In particular, the results from Table V show adhesively laminating an MD RR film and a TD RR film can balance the MD and TD tear resistance. Furthermore, the individual values for the Dynatup, MD tear resistance, and TD tear resistance properties are unexpectedly higher than the sum of the individual layers. Thus, the incrementally-stretched adhesively-laminated films provide a synergistic effect.

More specifically, as shown by the results from Table V, the TD tear resistance of the incrementally-stretched adhesively-laminated films can be greater than a sum of the TD tear resistance of the individual layers. Similarly, the MD tear resistance of the incrementally-stretched adhesively-laminated films can be greater than a sum of the MD tear resistance of the individual layers. Along related lines, the Dynatup peak load of the incrementally-stretched adhesively-laminated films can be greater than a sum of a Dynatup peak load of the individual layers.

TABLE VI Properties of Incrementally-Stretched Adhesively- Laminated Films (both layers MD and TD RR) Coat Gage Dynatup Dynatup Dart Wt. by Caliper Tensile Peak Energy to Drop MD TD g/sq. Wt. 1″ Foot Peel Load max load F50 Tear Tear ft. (mils) (mils) (g-f) (lb-f) (in. lb-f) (g) (g) (g) Sample 5 0.0300 0.64 1.71 81.5 11.5 11.28 254.0 418 511 Sample 6 0.0150 0.65 1.85 25.5 10.3 9.61 349 441 Sample 7 0.0100 0.67 1.81 27.6 10.6 9.34 264.0 353 406 Sample 8 0.0075 0.66 1.79 2.27 9.7 10.99 335 423 Sample 9 0.0060 0.66 1.87 7.79 9.9 12.21 260.0 319 450 Comparison Data Thicker NA 0.9 0.88 NA 4.3 3.8 180 262 843 Base Film

The results from Tables VI show that even with very low adhesive coating, superior Dynatup, MD tear resistance, and TD tear resistance properties are achieved compared to two layers of non-laminated film or one layer of thicker film. Additionally, the results from Tables VI in conjunction with the Comparison Data from Table V show that incrementally-stretched adhesively-laminated films of one or more implementations can allow for a reduction in basis weight (gauge by weight) as much as 50% and still provide enhanced strength parameters.

In addition to allowing for films with less raw material yet enhanced strength parameters, the results from Table VI further shows that incrementally-stretched adhesively-laminated films of one or more implementations can have an increased gauge (i.e., caliper) despite the reduction in basis weight. Some consumers may associate thinner films with decreased strength. Indeed, such consumers may feel that they are receiving less value for their money when purchasing thermoplastic film products with smaller gauges. One will appreciate in light of the disclosure herein that despite a reduction in raw material, incrementally-stretched adhesively-laminated films of one or more implementations may be and look thicker than a single layer of film with a higher basis weight. Thus, one or more implementations can enhance the look and feel of a film in addition to enhancing the strength parameters of the film.

In an additional example, one white layer of HDPE with a low MD tear resistance was cold stretched by MD ring rolling at 0.110 DOE. Another black layer of LLDPE was cold stretched by MD ring rolling at 0.110 DOE followed by TD ring rolling at 0.032 DOE and then laminated together with the same adhesive. Again, with the two ply laminates superior properties were obtained even at very low adhesive levels compared to a single ply film as shown by the results of Table VII.

TABLE VII Dynatup and Tear Resistance of Incrementally-Stretched Adhesively- Laminated Films (1 layer MD RR and 1 layer MD and TD RR) Coat Gage Dynatup Dynatup Dart Wt. by Peak Energy to Drop MD TD g/sq. Wt. Load max load F50 Tear Tear ft. (mils) (lb-f) (in. lb-f) (g) (g) (g) Sample 10 0.0300 0.67 11.83 11.86 284 357 575 Sample 11 0.0150 0.67 11.79 14.21 357 532 Sample 12 0.0100 0.67 10.99 10.77 288 373 502 Sample 13 0.0075 0.67 11.80 11.60 360 530 Sample 14 0.0060 0.67 12.60 10.57 260 385 535 Comparison Data Thicker NA 0.9 4.3 3.8 180 262 843 Base Film

In a final example, a bag formed from an incrementally-stretched adhesively-laminated film were compared to single ply bags of heavier basis weight using a consumer test with 17 lbs. of mixed garbage on an end use scale of 1-5. The laminate of two layers which were independently MD ring rolled and then TD ring rolled followed by adhesive lamination has an excellent score comparable to single layer bags of higher basis weight.

TABLE VIII End Use Testing Sample Gage by Wt. (mils) End use score Incrementally-Stretched 0.66 4.16 Adhesively-Laminated MD ring rolled single layer 0.80 4.08 Strainable network single layer 0.85 4.50

The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. Thus, the described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes that come within the meaning and range of equivalency of the claims are to be embraced within their scope. 

We claim:
 1. A double-walled thermoplastic bag comprising: a first thermoplastic bag having first and second opposing sidewalls joined together along a bottom edge, a first side edge, and a second, opposing side edge, wherein top edges of the first and second opposing sidewalls are at least partially un joined to form an opening to the first thermoplastic bag, the first thermoplastic bag including a first and second sections, the first and second sections each extending from the first side edge to the second side edge, the first section occupying a first area of the first thermoplastic bag and the second section occupying a second section of the first thermoplastic bag; a second thermoplastic bag positioned within the first thermoplastic bag, the second thermoplastic bag having third and fourth opposing sidewalls joined together along a bottom edge, a first side edge, and a second, opposing side edge, wherein top edges of the third and fourth opposing sidewalls are at least partially un joined to form an opening, the second thermoplastic bag including a first and second sections, the first and second sections each extending from the first side edge to the second side edge, the first section occupying a first area of the second thermoplastic bag and the second section occupying a second section of the second thermoplastic bag; a first plurality of non-continuous bonds securing the first section of the first thermoplastic bag to the first section of the second thermoplastic bag, the first plurality of non-continuous bonds comprise one of ultrasonic bonds, adhesive bonds, bonds formed from MD ring rolling, bonds formed from TD ring rolling, bonds formed from DD ring rolling, or bonds formed from SELFing; and a second plurality of non-continuous bonds securing the second section of the first thermoplastic bag to the second of the second thermoplastic bag, wherein the second plurality of non-continuous bonds differs in bond type from the first plurality of non-continuous—bonds, the second plurality of non-continuous bonds comprise one of ultrasonic bonds, adhesive bonds, bonds formed from MD ring rolling, bonds formed from TD ring rolling, bonds formed from DD ring rolling, or bonds formed from SELFing.
 2. The double-walled thermoplastic bag as recited in claim 1, wherein: the first thermoplastic bag includes a third section, the third section extending from the first side edge to the second side edge of the first thermoplastic bag, the third section occupying a third area of the first thermoplastic bag extending from the bottom edge toward the opening of the first thermoplastic bag; the second thermoplastic bag includes a third section, the third section extending from the first side edge to the second side edge of the second thermoplastic bag, the third section occupying a third area of the second thermoplastic bag extending from the bottom edge toward the opening of the second thermoplastic bag; and the double-walled thermoplastic bag is devoid of non-continuous bonds securing third section of the first thermoplastic bag to the third section of the second thermoplastic bag.
 3. The double-walled thermoplastic bag as recited in claim 2, wherein: the first thermoplastic bag includes a fourth section, the fourth section extending from the first side edge to the second side edge of the first thermoplastic bag, the fourth section occupying a fourth area of the first thermoplastic bag extending from proximate the opening of the first thermoplastic bag toward the bottom edge of the first thermoplastic bag; the second thermoplastic bag includes a fourth section, the fourth section extending from the first side edge to the second side edge of the second thermoplastic bag, the fourth section occupying a fourth area of the second thermoplastic bag extending from proximate the opening of the first thermoplastic bag toward the bottom edge of the second thermoplastic bag; and the double-walled thermoplastic bag is devoid of non-continuous bonds securing fourth section of the first thermoplastic bag to the fourth section of the second thermoplastic bag.
 4. The double-walled thermoplastic bag as recited in claim 3, wherein the third and fourth sections of the first and second thermoplastic bags are devoid of incremental stretching.
 5. The double-walled thermoplastic bag as recited in claim 4, wherein the first and second sections of the first and second thermoplastic bags are incrementally stretched.
 6. The double-walled thermoplastic bag as recited in claim 5, wherein the first plurality of non-continuous bonds comprise bonds formed from SELFing and the second plurality of non-continuous bonds comprise bonds formed from TD ring rolling.
 7. The double-walled thermoplastic bag as recited in claim 6, wherein the second sections of the first and second thermoplastic bags are devoid of non-continuous bonds formed from SELFing.
 8. The double-walled thermoplastic bag as recited in claim 1, wherein the first plurality of non-continuous bonds comprise bonds formed from TD ring rolling and the second plurality of bonds comprise bonds formed from MD ring rolling.
 9. The double-walled thermoplastic bag as recited in claim 8, wherein the second sections of the first and second thermoplastic bags are devoid of non-continuous bonds formed from TD ring rolling.
 10. The double-walled thermoplastic bag as recited in claim 1, wherein: the first plurality of non-continuous bonds comprise a first pattern; and the second plurality of non-continuous bonds comprise a second pattern differing from the first pattern.
 11. The double-walled thermoplastic bag as recited in claim 1, wherein the first plurality of non-continuous bonds and the second plurality of non-continuous bonds have a strength tailored to cause the bonds of the first plurality of non-continuous bonds and the second plurality of non-continuous bonds to fail prior to the first, second, third, or fourth sidewalls undergoing molecular-level deformation when a strain is applied to the double-walled thermoplastic bag.
 12. A multi-layer thermoplastic bag comprising: a first sidewall having an inner layer and an adjacent outer layer; a second sidewall having an inner layer and an adjacent outer layer, wherein the second sidewall is joined to the first sidewall along a first side edge, an opposing second side edge, and a bottom edge; and at least a portion of respective top edges of the first and second sidewalls define an opening of the multi-layered bag; non-continuous bonds of a first type securing a first section of the inner layer of first sidewall to a first section of the outer layer of the first sidewall, the first type of non-continuous bonds comprising one of ultrasonic bonds, adhesive bonds, bonds formed from MD ring rolling, bonds formed from TD ring rolling, bonds formed from DD ring rolling, or bonds formed from SELFing; and non-continuous bonds of a second type securing a second section of the inner layer of first sidewall to a second section of the outer layer of the first sidewall, the second type of non-continuous bonds comprising one of ultrasonic bonds, adhesive bonds, bonds formed from MD ring rolling, bonds formed from TD ring rolling, bonds formed from DD ring rolling, or bonds formed from SELFing.
 13. The multi-layer thermoplastic bag as recited claim 12, wherein the first type of non-continuous bonds and the second type of non-continuous bonds have a strength tailored to cause the bonds of the first type of non-continuous bonds and the second type of non-continuous bonds to fail prior to the inner or outer layers of the first sidewall undergoing molecular-level deformation when a strain is applied to the multi-layer thermoplastic bag.
 14. The multi-layer thermoplastic bag as recited claim 12, wherein the first and second sections of the inner and outer layers of the first sidewall comprise incremental stretching.
 15. The multi-layer thermoplastic bag as recited claim 14, wherein the entire inner and outer layers of the first sidewall comprise incremental stretching.
 16. The multi-layer thermoplastic bag as recited claim 14, wherein an upper section directly adjacent the opening of each of the inner and outer layers of the first sidewall are devoid of incremental stretching and devoid of non-continuous bonds of the first type and the second type.
 17. The multi-layer thermoplastic bag as recited claim 16, wherein a bottom section of each of the inner and outer layers of the first sidewall that directly adjacent a hem seal are devoid of incremental stretching and devoid of non-continuous bonds of the first type and the second type.
 18. The multi-layer thermoplastic bag as recited in claim 12, wherein the first type of non-continuous bonds comprise bonds formed from SELFing and the second type of non-continuous bonds comprise bonds formed from TD ring rolling.
 19. The multi-layer thermoplastic bag as recited in claim 18, wherein the second sections of the inner and outer layers of the first sidewall are devoid of non-continuous bonds formed from SELFing.
 20. The multi-layer thermoplastic bag as recited in claim 12, wherein the first type of non-continuous bonds comprise bonds formed from TD ring rolling and the second type of bonds comprise bonds formed from MD ring rolling. 